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Applications piezoelectric devices

The deposition temperature range is 300-500°C, the partial pressure of the alkyl is 0.5-2.5 Torr, and that of THF is 20-80 Torr. ZnO has found applications in piezoelectric devices, transducers, coatings for photoconductive devices, and non-linear resistors (varistors), and overvoltage protectors. [Pg.314]

Piezoelectric biomaterials, 3 748-750 Piezoelectric ceramics, 1 708-710 U.S. market trends, l 710t Piezoelectric coefficient tensor, 11 93, 94 Piezoelectric crystals, 17 423 in acoustic wave sensors, 22 270 Piezoelectric devices, applications of, 11 103-104... [Pg.707]

Zinc oxide occurs in nature as mineral zincite. It is the most important zinc compound and has numerous industrial applications. Zinc oxide is the pigment in white paints. It is used to make enamels, white printing inks, white glue, opaque glasses, rubber products and floor tiles. It is used in cosmetics, soaps, pharmaceuticals, dental cements, storage batteries, electrical equipment, and piezoelectric devices. Other applications are as a flame retardant, as a UV absorber in plastics, and a reagent in analytical chemistry. A major application of zinc oxide is in the preparation of most zinc salts. In medicine, the compound is used as an antiseptic, an astringent and a topical protectant. [Pg.990]

Piezoelectric devices have found a host of other aerospace applications. For example, one of the most troublesome problems faced by airlines is the detection of tiny hairline fractures in an aircraft body. These fractures often appear long before they can be observed visually during routine maintenance procedures. Yet, once they begin to develop, they can quite suddenly and dramatically lead to much larger cracks and failures that result in disastrous accidents. For this reason, airline companies are constantly... [Pg.119]

A filter is required to pass a certain selected frequency band, or to stop a given band. The passband for a piezoelectric device is proportional to k2, where k is the appropriate coupling coefficient. The very low k value of about 0.1 for quartz only allows it to pass frequency bands of approximately 1% of the resonant frequency. However, the PZT ceramics, with k values of typically about 0.5, can readily pass bands up to approximately 10% of the resonant frequency. Quartz has a very high Qm (about 106) which results in a sharp cut-off to the passband. This, coupled with its very narrow passband, is the reason why the frequency of quartz oscillators is very well defined. In contrast PZT ceramics have Qm values in the range 102—103 and so are unsuited to applications demanding tightly specified frequency characteristics. [Pg.399]

Ferroelectric ceramics and single crystals have found wide applications in many electronic, acoustoptic and piezoelectric devices [1,2], Perovskites represent one of the most important classes of inorganic powders that are of great interest in functional ceramics used for electronic components among them BaTiOj is a typical and most frequently used representative. [Pg.85]

The response of piezoelectric devices propagating shear horizontal acoustic plate modes (SH-APMs) has been modeled and experimentally characterized for variations in surface mass, liquid rheological properties, and solution dielectric coefficient and electrical conductivity. The nature of the SH-APM and its propagation characteristics are outlined and used to describe a range of Interactions at the solid/liquid interface. Sensitivity to sub-monolayer mass changes is demonstrated and a Cu sensor is described. The APM device is compared to the surface acoustic wave device and the quartz crystal microbalance for liquid sensing applications. [Pg.191]

Actuators are among the latest applications for thin sheets of piezoelectric materials. Actuators are small displacement elements for the precision positioning of optical and other motors and machinery. All of these piezoelectric devices operate on the principle of electric field-induced strain. [Pg.216]

The application of cross-linker can produce other effects as well. For example, Matsuguchi et al. (2003) analyzed the influence of cross-linker on the characteristics of QCM-based SO sensors and found that sensors with cross-linked structure had lower sorption ability but faster sorption/desorption rates. The latter is known to be very important for sensors designed for in situ measurements. In the case of poly(styrene-co-chloromethyl styrene), the use of the cross-linked structure clearly increased the sensitivity to NOj of piezoelectric devices (Matsuguchi et al. 2005). [Pg.344]

These present and future applications of piezoelectric devices all hinge upon their ability to transduce physical strains occurring in a solid to electrical potentials and vice versa. Strains are relative displacements of particles within a solid and cause the generation of restoring stress forces. Strains will also result in the establishment of electrical fields within the solid if the material is piezoelectric. [Pg.295]

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See also in sourсe #XX -- [ Pg.21 , Pg.23 , Pg.24 ]



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